KR101584544B1 - Seed disinfecting apparatus - Google Patents

Abstract

The present invention relates to a seed sterilizing apparatus which includes a sterilizing tank filled with hot water for sterilizing seeds and a washing tank filled with cool water for washing the sterilized seeds. The seed sterilizing apparatus includes two-stage boilers on upper and lower ends to supply the hot water to the sterilizing tank. The upper boiler includes: an outer chamber which forms the outer surface and has flowing water therein; side chambers which are arranged on both sides of the outer chamber and have a side member connected to the outer chamber; and a heat exchange pipe arranged to connect the side chambers. The lower boiler includes: a heater arranged on the inside; an outer chamber which forms the outer chamber while being spaced apart from the chamber and is connected to the outer chamber of the upper boiler; side chambers which are arranged on both sides being spaced apart from the outer chamber and have a side member connected to the side member of the upper boiler; a heat exchange pipe arranged to connect the side chambers; and a discharging chamber which is arranged to be connected to a side chamber to supply hot water to the sterilizing tank.

Description

Seed disinfecting apparatus -

The present invention relates to a seed disinfection apparatus, and more particularly, to a seed disinfection apparatus capable of disinfecting seeds in a disinfection tank for hot water and cleaning the seeds in a washing tank for cold water.

In general, plant seeds, especially seeds of cereals, are a starting point for direct connection with the yield of crops, so it is very important to secure seeds that are fundamentally healthy or to keep the seeds healthy.

There is chemical disinfection as a method of disinfecting the seeds in order to secure healthy seeds or to keep seeds healthy so as to eliminate germs and nematodes of seeds infection.

Typical examples of chemical disinfection include immersion disinfection in which the seed is immersed in an aqueous solution of the pesticide for a certain period of time, and disinfection of the material in which the pesticide powder is directly applied to the seed.

In recent years, however, there has been a growing interest in organic agricultural products, and there has been a proliferation of eco-friendly agricultural products and methods of cultivation. Therefore, disinfection techniques that can sterilize seeds without using pesticides instead of chemical disinfection using seed pesticides are required .

Therefore, the seed sterilization tank is filled with hot water, and the seed is soaked and dispensed to physically disinfect germs and nematodes in the seed.

Korean Patent No. 10-1250034 (hereinafter referred to as " Prior Art Document 1 ") of the physical disinfection method using hot water as described above includes a disinfection tank filled with hot water for seed disinfection and having a discharge port formed at a lower side of one side; A box for storing a bag filled with a seed for disinfection and a storage frame for storing the box; An ascending / descending means installed on the disinfecting tank and moving up and down the storage frame in which the seed sack is stored; A hot water supply unit connected to the disinfection unit to supply and circulate hot water into the disinfection unit; And a control unit electrically connected to the disinfection unit and automatically controlling the supply of hot water through the hot water supply unit and the elevation of the storage frame through the elevation unit, A plurality of drawer-shaped dividers are formed at one time to accommodate a large number of boxes, and the lower end of the storage frame is connected to a second air injection device provided outside the disinfection unit, And the hot water is uniformly supplied to the inside of the seed.

In the seed sterilizing apparatus disclosed in this prior art document 1, the hot water heated by the boiler is supplied to the disinfection tank, and the seed is disinfected in the hot water of the disinfection tank.

On the other hand, in the conventional seed disinfecting apparatus disclosed in the prior art document 1, hot water is heated in the boiler and the generated hot water is supplied to the disinfection unit. At this time, the temperature of the hot water required for disinfection is 60 ° C or more.

However, in the prior art document 1, since the water is heated by only one boiler, it takes a long time to heat the water up to the temperature of the hot water required for the disinfection of the seed, There is a drawback that the workability is poor.

The above-described seed sterilizing apparatus and the technology therefor are described in detail in the following prior art documents, so that detailed description thereof will be omitted.

Korean Patent No. 10-1250034

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems of the conventional art, and it is an object of the present invention to provide a disinfection apparatus, The present invention has been made to solve the above problems.

In order to accomplish the above object, the present invention provides a seed sterilizing apparatus comprising a disinfection tank filled with hot water for sterilizing seeds and a washing tank filled with cold water for washing sterilized seeds, The apparatus includes a boiler for supplying hot water to the disinfecting tank in two upper and lower stages, an upper chamber forming outer side surface thereof and an outer chamber through which water flows; Side chambers which are provided at both ends of the outer chamber and whose one side member is connected to communicate with the outer chamber; And a heat exchange pipe provided so as to communicate the both side chambers, wherein the lower boiler includes a heater provided therein; An outer chamber spaced apart from the heater to form an outer surface and to be connected to the outer chamber of the upper boiler so as to communicate with the outer chamber; A side chamber disposed at both ends separated from the outer chamber and having one side member communicating with one side chamber of the upper boiler; A heat exchange pipe provided to communicate the both side chambers; And a discharge chamber communicating with the one side chamber and supplying hot water to the disinfecting tank.

Each side chamber of the upper boiler is formed with compartments for isolating the inner space from upper and lower sides and the other side chamber is formed with compartments for isolating the upper and lower spaces from each other. So as to be continuously communicated with each other.

Further, a compartment for radially isolating the inner space is formed in one side chamber of the lower boiler, and a compartment for isolating the inner space in the quadrant is formed in the other side chamber, and each compartment of the both side chambers is connected to a heat exchange pipe And may be provided so as to be continuously communicated.

In addition, the inside of the lower boiler provided with the heaters and the heat exchange pipe and the inside of the upper boiler provided with the heat exchange pipe may be communicated with the communication pipe.

According to the seed sterilizing apparatus of the present invention, the boiler is constituted by the upper and lower two stages in the main body close to the disinfection tank, and the water is continuously heated to the disinfection tank twice in succession to supply hot water quickly. Can be rapidly disinfected.

According to the seed sterilizing apparatus of the present invention, the water circulating through the upper boiler and the lower boiler is sequentially passed through the outer chamber, the side chamber, and the heat exchange pipe partitioned by each boiler, thereby increasing the heat exchange efficiency, There are advantages to be able to.

1 is a plan view of a seed sterilizing apparatus according to the present invention.
FIG. 2 is a front view of a boiler constructed in the seed sterilizing apparatus of the present invention.
3 is a rear view of the boiler constructed in the seed sterilizing apparatus of the present invention.
4 is a front cross-sectional view of a boiler constructed in the seed sterilizing apparatus of the present invention.
5 is a rear sectional view of a boiler constructed in the seed sterilizing apparatus of the present invention.
6 is a side cross-sectional view of a boiler constructed in the seed sterilizing apparatus of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terms used in the present invention are defined in consideration of the functions of the present invention and may vary depending on the intention or custom of the user or the operator. Therefore, the definitions of these terms are meant to be in accordance with the technical aspects of the present invention As well as the other.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention and are incorporated in and constitute a part of this specification. Embodiments that include components replaceable as equivalents in the components may be included within the scope of the present invention.

In addition, optional terms in the following embodiments are used to distinguish one element from another element, and the element is not limited by the terms. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of related arts which may unnecessarily obscure the gist of the present invention will be omitted.

1 to 6 are views showing a seed sterilizing apparatus according to the present invention.

1 and 2, a seed sterilizing apparatus 100 according to the present invention includes a sterilizing tank 210 for sterilizing seeds, a main body 200 having a washing tank 220 for washing sterilized seeds And a boiler 300 (400) provided on one side of the main body 200 to supply hot water to the disinfecting tank 210.

The hot water supplied from the boilers 300 and 400 is stored in the disinfection tank 210 of the main body 200 and the hot water in the disinfection tank 210 is maintained at 60 to 70 ° C to improve the disinfection effect of the seed The hot water is circulated through the disinfection unit 210 and the boiler 300 (400) by the pump 480 to maintain the temperature of the hot water constant.

In the washing tank 220 provided close to the disinfecting tank 210, cold water for washing the disinfected seed in the disinfecting tank 210 is stored.

The disinfecting tank 210 and the washing tub 220 are installed in a state of being held in a watertight state by being inserted into the upper surface of the main body 200 in the form of a normal container.

A support bar 230 having a predetermined height is rotatably installed in the main body 200 between the disinfection unit 210 and the washing tub 220. The support bar 230 rotates Preferably, a motor and gear means are provided in the main body 200 to rotate the support 230 electrically.

A hightness 240 is provided on the horizontal portion of the supporter 230 parallel to the upper surface of the main body 200. The hite 240 can vertically move the turret-containing turret, The turret can be rotated in a clamped state.

Therefore, the bag containing the seeds can be immersed and disinfected in the disinfection tank 210 by the supporter 230 and the gypsum 240, taken out from the disinfection tank 210 after the disinfection, The disinfection and cleaning of the seed can be performed quickly and easily.

A control unit 250 is installed in the main body 200 between the disinfection unit 210 and the boilers 300 and 400. The control unit 250 controls the operations of the support unit 230 and the hightness unit 240, And controls the overall operation of the device 100.

As shown in FIG. 2, the boilers 300 and 400 may include an upper and a lower boiler 300 and a lower boiler 400 stacked on one side of the main body 200, that is, Stage structure.

As shown in FIGS. 4 to 6, the upper boiler 300 includes an outer chamber 310 through which water flows in the outer chamber 310, an outer chamber 310 at one end of the outer chamber 310, Side chambers 320 and 320a communicably connected to the outer chamber 310 and a plurality of heat exchange pipes 330 communicating the both side chambers 320 and 320a.

The outer chamber 310 is provided in a double panel having a shape of " H "shape provided on a bottom plate of a single panel and having a space in which water can flow, And is connected to the outer chamber 310 of the lower boiler 400 while communicating with the outer chamber 320 of the lower boiler 400.

On the other hand, the both side chambers 320 and 320a are provided in a double panel having a space in which water can flow, as in the outside chamber 310, and the both side chambers 320 and 320a are provided in the inside space Is divided into a plurality of compartments 320-1 to 320-6 and 320a-1 to 320a-4 by a plurality of partition plates 321, respectively.

That is, one side chamber 320 of the front portion of the upper boiler 300 is divided into six compartments 320-1 to 320-4, which are partitioned by longitudinal and transverse partitioning plates 321 as shown in FIG. And the other side chamber 320a of the rear portion of the upper boiler 300 is divided into four compartments 320a-320b by the lateral partition plate 321 as shown in FIG. 3, 1 to 320a-4) are separated and separated only on the upper and lower sides.

Accordingly, the water introduced into the two side chambers 320 and 320a passes through the compartments 320-1 to 320-6 and 320a-1 to 320a-4 in a zigzag manner from the upper side to the lower side.

A plurality of heat exchange pipes 330 are stacked in one direction in the upper boiler 300 and the opposite ends of the heat exchange pipes 330 are stacked on both side chambers 320 and 320a, And the water is allowed to flow while moving in both side chambers 320 and 320a in a zigzag manner.

Particularly, as shown in FIG. 2, when the heat exchange pipe 330 is arranged in six lines in the upper boiler 300, the right side of the one side chamber 320 provided on the front surface of the upper boiler 300 The upper compartment 320-1 is provided with one row of heat exchange pipes 330 and the left upper compartment 320-2 is provided with two rows of heat exchange pipes 330. The left central compartment 320-3 is provided with three rows of Three rows of heat exchange pipes 330 are provided in the right central compartment 320-4 and two rows of heat exchange pipes 330 are provided in the right lower compartment 320-5, In the lower compartment 320-6, one row of heat exchange pipes 330 is provided. Accordingly, in the one side chamber 320, the left and right compartment 320-1 to 320-6 are provided at different heights.

3, the other side chamber 320a provided on the rear surface of the upper boiler 300 has a structure in which the left and right sides are not separated from each other but connected to each other. In the upper compartment 320a-1, And two rows of heat exchange pipes 330 are provided in the center upper and middle lower compartments 320a-2 and 320a-3 respectively and one row of heat exchange pipes 330 are provided in the lower compartment 320a-4 Respectively. Therefore, the upper and lower compartments 320a-1 to 320a-4 of the other side chamber 320a are isolated from each other.

The flow of water in the upper boiler 300 in a state where the two side chambers 320 and 320a are communicated by the plurality of heat exchange pipes 330 will be described below. And then flows into the upper compartment 320-1 of the side chamber 320 through the heat exchange pipe 330 and then flows into the upper compartment 320a-1 of the other side chamber 320a, 1 through the other heat exchange pipe 330 in the compartment 320-2 and into the upper left compartment 320-2 of the one side chamber 320 through the other heat exchange pipe 330 in the compartment 320-2, 2 of the one side chamber 320 through the other heat exchange pipe 330 in the compartment 320a-2 to the upper and lower upper compartments 320a-1, 320a-2, (In this case, more water flows into the right central compartment 320-4 than the left central compartment 320-3), and The inflow water again flows into the lower central compartment 320a-3 of the other side chamber 320a through the different heat exchange pipes 330 in the compartments 320-3 and 320-4, Through the other heat exchange pipe 330 in the compartment 320 - 5 to the lower right compartment 320 - 5 of the side chamber 320 through the other heat exchange pipe 330 in the compartment 320 - Is introduced into the lower compartment 320a-4 of the side chamber 320a through the other heat exchange pipe 330 in the compartment 320a-4 to the left lower compartment 320-6 of the one side chamber 320 And is supplied to the outer chamber 420 of the lower boiler 400 to be described later.

Accordingly, the water discharged after the circulation of the upper boiler 300 is indirectly heated in the upper boiler 300 and supplied to the lower boiler 400 in a sufficiently preheated state, so that hot water can be generated quickly.

Meanwhile, a hollow heat discharge pipe 340 penetrates the outer chamber 310 at the upper part of the upper boiler 300, so that the heat inside the upper boiler 300 is dissipated properly to the outside, It is possible to prevent overheating of the battery 300.

A fuel tank 350 for supplying fuel to the heater 470 provided in the lower boiler 400 to be described later may be installed on one side of the upper boiler 300 and a fuel tank 350 for supplying fuel to the heater 470, (Not shown), which is controlled by the control unit 250, may be provided in a conduit (not shown)

4 to 6, the lower boiler 400 is separated from the heater 470 by the heater 470 provided therein and forms the outer side surface while the outer chamber 310 of the upper boiler 300, And an outer chamber 420 connected to the outer chamber 420 and connected to the outer chamber 420. The inner chamber 420 is connected to the inner chamber 420 and the outer chamber 420. The inner chamber 420 is connected to the one side chamber 320 of the upper boiler 300, A plurality of heat exchange pipes 440 provided to communicate the two side chambers 430 and 430a and the two side chambers 430 and 430a and a plurality of heat exchange pipes 440 connected to the one side chamber 430 to supply hot water to the disinfection tank 210 (Not shown).

The lower boiler 400 includes an octagonal body having seven outer chambers 420, four exhaust chambers 460 and two side chambers 430 and 430a, A mounting pipe 410 is installed at a central portion of one side chamber 430 on the front side and a heater 470 is inserted into the mounting pipe 410 to be installed inside the lower boiler 400. Therefore, the heat generated by the heater 470 heats the lower boiler 400 and is transferred into the upper boiler 300 through the communication pipe 450, which will be described later, to heat the upper boiler 300.

The outer chamber 420 is formed of a double panel having a space in which water can flow and is formed to communicate with the outer chamber 310 and the disinfecting tank 210 of the upper boiler 300. The low-temperature water discharged from the disinfecting tank 210 flows into the outer chamber 420 of the lower boiler 400 and is supplied to the outer chamber 310 of the upper boiler 300 again, And then flows into the side chamber 430 at one side of the lower boiler 400 again.

The discharge chamber 460 is a square pipe provided at the upper end of the outer chamber 420. The discharge chamber 460 is provided at one end thereof in communication with the one side chamber 430 to be described later and at the other end thereof with a disinfection tank 210 So that hot water generated in the lower boiler 400 is directly supplied to the disinfecting tank 210.

The both side chambers 430 and 430a are formed of a double panel having a space in which water can flow, and the inside spaces of the both side chambers 430 and 430a are divided into a plurality of diaphragms 431, And 430a-1 to 430a-4, respectively, by a plurality of compartments 430-1 to 430-5.

That is, one side chamber 430 of the front side of the lower boiler 400 is divided into five compartments 430-1 to 430-5 radially partitioned by the partition 431 as shown in FIG. 2 The other side chamber 430a of the rear portion of the lower boiler 400 is partitioned into quadrants by four compartments 430a-1 to 430a-4 formed by the partition plate 431 as shown in FIG.

Accordingly, the water flowing into the both side chambers 430 and 430a passes through the respective compartments 430-1 to 430-5 (430a-1 to 430a-4) in a zigzag manner.

In the lower boiler 400, a plurality of heat exchange pipes 440 are arranged side by side with arcs on both sides. The heat exchange pipes 440 are installed at both ends of the side heat exchanger pipes 440, 430a-1 to 430a-4 of the first chamber 430a so that water can flow while moving in both side chambers 430 and 430a in a zigzag manner.

That is, as shown in FIG. 2, in the structure in which twelve heat exchange pipes 440 are provided in the left and right sides in the interior of the lower boiler 400, Three heat exchange pipes 440 are provided in the right upper compartment 430-1 of the chamber 430 and six heat exchange pipes 440 are provided in the right central compartment 430-2 and the lower compartment 430- Three heat exchange pipes 440 are disposed on the left and right sides of the upper compartment 440. The left central compartment 430-4 is provided with six heat exchange pipes 440 and the upper left compartment 430- 5 are provided with three heat exchange pipes 440 and a discharge chamber 460.

3, the left upper compartment 430a-1 of the other side chamber 430a provided on the rear surface of the lower boiler 400 (the right upper compartment with reference to FIG. 2, The left and right sides of the compartment 430a are divided into five compartments 430a-1 to 430a-4 of the compartment 430a-1 to 430a-4) Seven heat exchange pipes 440 are provided in the right lower compartment 430a-3 and five heat exchange pipes 440 are provided in the right upper compartment 430a-4 Respectively.

The flow of water in the lower boiler 400 in a state where the two side chambers 430 and 430a are communicated by the plurality of heat exchange pipes 440 will be described below. And flows into the upper left compartment 430-1 of the other side chamber 430a through the heat exchange pipe 440 (see FIG. 2) 3) is again introduced into the right central compartment 430-2 of the one side chamber 430 through the other heat exchange pipe 440 in the compartment 430a-1, 2 through the other heat exchange pipe 440 and into the lower left compartment 430a-2 of the other side chamber 430a through the other heat exchange pipe 440 in the compartment 430a-2, And the inflowing water flows into the lower compartment 430-3 of the one side chamber 430 Is introduced into the lower right compartment 430a-3 of the other side chamber 430a through another heat exchange pipe 440 located on the opposite side of the heat exchanger pipe 440, And flows into the left central compartment 430-4 of the chamber 430 through the other heat exchange pipe 440 in the compartment 430-4 to the right upper compartment 430a-4 of the other side chamber 430a Which is again introduced into the left upper compartment 430-5 of one side chamber 430 through another heat exchange pipe 440 in the compartment 430a-4.

The water circulating in the lower boiler 400 is directly heated by the heater 470 provided in the lower boiler 400 to be hot water. The hot water thus generated is finally supplied to the upper left side of the one side chamber 430 Flows into the compartment 430-5 and is supplied to the disinfecting tank 210 through the discharge chamber 460. [

A communication pipe 450 is installed between the lower boiler 400 having the heater 470 and the heat exchange pipe 440 and the upper boiler 300 having the heat exchange pipe 330 and the lower boiler 400, The heat generated by the heater 470 of the lower boiler 400 is transferred into the upper boiler 300 through the communication pipe 450 by communicating the inside of the upper boiler 300 with the inside of the upper boiler 300. [ Thus, the low-temperature water circulating in the upper boiler 300 is indirectly heated by the heat of the heater 470 transferred into the upper boiler 300.

The water of the disinfecting tank 210 can be circulated smoothly to the lower boiler 400, the upper boiler 300, the lower boiler 400, and the disinfection tank 210 on one side of the lower boiler 400 A pump 480 is provided, and such a pump 480 is preferably provided with a water pump.

The operation of the seed sterilizing apparatus according to the present invention will now be described.

First, in operation of the seed sterilizing apparatus 100, boilers 300 and 400 for supplying hot water to the disinfecting tank 210 of the main body 200 are operated.

That is, the heater 470 inserted in the mounting pipe 410 of the lower boiler 400 is operated to heat the inside of the lower boiler 400 by the heat of the heater 470, The heated heat is transferred to the inside of the upper boiler 300 through the communicating pipe 450 to heat the inside of the upper boiler 300.

In addition to the operation of the heater 470 as described above, the pump 480 is operated to cause the water stored in the disinfecting tank 210 of the main body 200 to flow into the outer chamber 420 of the lower boiler 400, The water filled in the outer chamber 420 of the lower boiler 400 flows into the outer chamber 310 of the upper boiler 300 again.

The water filled in the outer chamber 310 of the upper boiler 300 flows into the upper right compartment 320-1 of the one side chamber 320 of the upper boiler 300 (Refer to FIG. 3) of the other side chamber 320a through the heat exchange pipe 330 provided in the compartment 320-1 and flows into the upper compartment 320a-1 Water flows into the left upper compartment 320-2 of the one side chamber 320 through another heat exchange pipe 330 of the upper compartment 320a-1.

The water flowing into the upper left compartment 320-2 flows into the upper upper compartment 320a-2 of the other side chamber 320a through another heat exchange pipe 330 installed in the upper upper compartment 320-2, -2 are introduced into the left and right central compartments 320-3 and 320-4 of the one side chamber 320 through another heat exchange pipe 330 installed in the compartment 320a-2 thereof, do. The water flowing into the left and right central compartments 320-3 and 320-4 of the one side chamber 320 is supplied to the right central compartment 320-4 from the left central compartment 320-3 with more water . 2 and 3, two rows of heat exchange pipes 330 installed in the upper central compartment 320a-2 of the other side chamber 320a are connected to the left central compartment 320- 3 are provided with only one row. By providing two rows in the right central compartment 320-4, more water flows into the right central compartment 320-4.

The water flowing into the left and right central compartments 320-3 and 320-4 of the one side chamber 320 again flows through the other heat exchange pipe 330 to the center lower side of the other side chamber 320a, Is introduced into the compartment 320a-3 through the other heat exchange pipe 330 in the compartment 320a-3 and into the lower right compartment 320-5 of the one side chamber 320, 4 to the lower compartment 320a-4 of the other side chamber 320a through the other heat exchange pipe 330 in the compartment 320a-4, Flows into the lower left compartment 320-6 of the chamber 320 and is supplied to the lower portion of the outer chamber 420 of the lower boiler 400 to be described later.

The water circulating through the outer chamber 310 of the upper boiler 300 and the two side chambers 320 and 320a and the plurality of heat exchange pipes 330 in a zigzag manner is circulated in the upper boiler 300 Indirectly heated by the heating of the heater 470 and preheated.

At this time, a part of the heat transmitted into the upper boiler 300 is radiated to the outside through the heat exhaust pipe 340 on the upper surface of the upper boiler 300, thereby preventing the overheating of the upper boiler 300.

The water preheated in the upper boiler 300 flows into the upper right compartment 430-1 of one side chamber 430 of the lower boiler 400 (see FIG. 2) (See FIG. 3) of the other side chamber 430a through the other heat exchange pipe 440 in the upper side chamber 430-1 (see FIG. 3), and the inflow water flows into the upper compartment 430a-1 Through the other heat exchange pipe 440 in the compartment 430-2 to the left central compartment 430-2 of the one side chamber 430 and the introduced water again flows through the other heat exchange pipe 440 in the compartment 430-2 to the other side And flows into the left lower compartment 430a-2 of the side chamber 430a.

The inflow water flows into the lower compartment 430-3 of the one side chamber 430 through the other heat exchange pipe 440 in the compartment 430a-2, Is introduced into the lower right compartment 430a-3 of the other side chamber 430a through another heat exchange pipe 440 located on the opposite side of the inside of the lower compartment 430-3 of the side chamber 430, Is introduced into the left central compartment 430-4 of the one side chamber 430 again via the other heat exchange pipe 440 in the compartment 430a-3, which again passes through the other heat exchange pipe 440 in the compartment 430-4 The upper compartment 430a-4 of the other side chamber 430a through the other heat exchange pipe 440 in the compartment 430a-4 to the left upper compartment 430- 5).

The water circulating in the lower boiler 400 is directly heated by the heater 470 provided in the lower boiler 400 to be rapidly heated. The hot water thus generated is finally heated to the temperature of the one side chamber 430 Enters the left upper compartment 430-5 and is supplied to the disinfecting tank 210 through the discharge chamber 460. [

Therefore, the bag containing the seed is sterilized in the disinfection tank 210 using the gypsum 240, and the disinfection tank 210 is taken out from the disinfection tank 210 after sterilization, The seed can be disinfected and cleaned quickly and easily.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the same is by way of illustration and example only and is not to be construed as limiting the present invention. It is obvious that the modification or improvement is possible.

It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

100: Seed sterilizing apparatus 200:
210: disinfection tank 220: washing tank
230: support 240: hoist
250: control unit 300, 400: boiler
310: outer chamber 320, 320a: side chamber
320-1 to 320-6: compartments 320a-1 to 320a-4: compartments
321: diaphragm 330: heat exchange pipe
340: Heat exhaust pipe 350: Fuel pipe
410: mounting tube 420: outer chamber
430, 430a: Side chambers 430-1 to 430-5:
430a-1 to 430a-4: compartment 431: diaphragm
440: Heat exchange pipe 450: Communicating pipe
460: exhaust chamber 470: heater
480: Pump

Claims (4)

A seed sterilizing apparatus comprising a disinfection tank filled with hot water for sterilizing seeds and a washing tank filled with cold water for washing the disinfected seeds,
The seed sterilization apparatus includes a boiler for supplying hot water to the disinfection tank in two stages,
The upper boiler having an outer chamber forming an outer side thereof and an inner chamber through which water flows;
Side chambers which are provided at both ends of the outer chamber and whose one side member is connected to communicate with the outer chamber; And
And a heat exchange pipe provided to communicate the both side chambers,
The lower boiler includes a heater disposed therein;
An outer chamber spaced apart from the heater to form an outer surface and to be connected to the outer chamber of the upper boiler so as to communicate with the outer chamber;
A side chamber disposed at both ends separated from the outer chamber and having one side member communicating with one side chamber of the upper boiler;
A heat exchange pipe provided to communicate the both side chambers; And
And a discharge chamber communicating with the one side chamber and supplying hot water to the disinfection unit.
The method according to claim 1,
The side chamber of the upper boiler is provided with compartments for isolating the inner space from upper and lower sides and the other side chamber is provided with compartments for isolating the upper and lower spaces from each other. And the seed sterilizing device is provided in communication with the seed sterilizing device.
The method according to claim 1 or 2,
A side chamber of the lower boiler is formed with a compartment for radially isolating the inner space, and a compartment for isolating the inner space by a quadrant is formed in the other side chamber. The compartments of the both side chambers are continuously connected by a heat exchange pipe The seed sterilizing device being provided to be communicated.
The method of claim 3,
Wherein the inside of the lower boiler provided with the heaters and the heat exchange pipe and the inside of the upper boiler provided with the heat exchange pipe are communicated with the communication pipe.

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